US3621453A - Electrofluidic delay line oscillator - Google Patents
Electrofluidic delay line oscillator Download PDFInfo
- Publication number
- US3621453A US3621453A US834840A US3621453DA US3621453A US 3621453 A US3621453 A US 3621453A US 834840 A US834840 A US 834840A US 3621453D A US3621453D A US 3621453DA US 3621453 A US3621453 A US 3621453A
- Authority
- US
- United States
- Prior art keywords
- pneumatic
- frequency
- tubing
- delay line
- electrical
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Images
Classifications
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03B—GENERATION OF OSCILLATIONS, DIRECTLY OR BY FREQUENCY-CHANGING, BY CIRCUITS EMPLOYING ACTIVE ELEMENTS WHICH OPERATE IN A NON-SWITCHING MANNER; GENERATION OF NOISE BY SUCH CIRCUITS
- H03B5/00—Generation of oscillations using amplifier with regenerative feedback from output to input
- H03B5/30—Generation of oscillations using amplifier with regenerative feedback from output to input with frequency-determining element being electromechanical resonator
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K11/00—Measuring temperature based upon physical or chemical changes not covered by groups G01K3/00, G01K5/00, G01K7/00 or G01K9/00
- G01K11/22—Measuring temperature based upon physical or chemical changes not covered by groups G01K3/00, G01K5/00, G01K7/00 or G01K9/00 using measurement of acoustic effects
- G01K11/26—Measuring temperature based upon physical or chemical changes not covered by groups G01K3/00, G01K5/00, G01K7/00 or G01K9/00 using measurement of acoustic effects of resonant frequencies
Definitions
- a closed loop oscillator circuit consists of a tub- [52] US. Cl 331/64, ing of predetermined length, an electricahtwpneumatic trans 73/339 A, 331/66, 331/155, 33 H162 ducer, a pneumatic-to-electrical transducer and an electronic [5l Int. Cl "03!) 5/34 amplifier
- the electricamwpneumatic transducer converts an Field of Search 331/64-66, electrical frequency signal to a pneumatic frequency Signal 162; 73/339 A which generates pressure waves in a gaseous medium within the tubing.
- the tube length corresponds to one or multiple [56] References Cited half-wavelengths of a reference frequency of oscillation.
- the UNITED STATES PATENTS electronic amplifier provides sufficient gain to maintain selfl,92l,50l 8/1933 Bower 331/ sustained oscillation in the closed loop circuit.
- the tempera- 2,949,l66 8/1960 Coleman et al... 331/155 X ture or gas content (ratio) of the gaseous medium within the 3,136,226 6/l965 Milne?
- v 73/3 tubing can be determined from the actual oscillation frequen- 3 39 979 11/1965 Miller 73/339 W /Z /0 a f-P mw- Qfl wo/c puny UM! U 006.4% I I 0!?
- Our invention relates to an oscillator circuit, and in particu lar, to an electrofluidic oscillator employing a tubing as a delay line of predetermined length corresponding to one or multiple half-wavelengths of a reference frequency of oscillation.
- the invention herein described was made in the course of or under a contract or subcontract thereunder, with the Department of the Navy.
- Fluid oscillator circuits are employed in many fluidic control systems for purposes such as generating pressurized fluid pulsations of fixed and variable frequency corresponding respectively to the reference and actual value of a system parameter being controlled.
- Oscillators which are all-fluidic (i.e., utilize fluid amplifiers having no moving mechanical parts) are known and have many useful applications; however, such conventional all-fluidic oscillators are generally not suitable in gas-monitoring systems wherein the fluid amplifiers are supplied with a pressurized gas other than the gaseous medium being sensed.
- an allfluidic oscillator is used to determine particular gas properties in a gas mixture, the introduction of a foreign gas via the fluid amplifier power fluid supply would result in a false indication of such properties.
- one of the principal objects of our invention is to provide a hybrid-type delay line oscillator.
- Another object of our invention is to provide an electrofluidic delay oscillator adapted for determining particular properties of a gaseous medium.
- a further object of our invention is to provide an electrofluidic delay line oscillator adapted for determining the gas content or temperature of a gas mixture of known gases.
- our invention is an electrofluidic delay line oscillator which utilizes a tubing having a predetermined length corresponding to one or multiple half wavelengths of a particular or reference frequency of oscillation.
- the tubing is in a gaseous medium and is provided with an aperture located at each antinode of a reference frequency pneumatic pressure standing wave generated within the tubing, the aperture providing passage means through the tube wall for the gaseous medium.
- Suitable transducers and an electronic amplifier are connected in a closed loop circuit with the tubing, the amplifier providing sufficient gain to maintain self-sustained oscillation in the circuit.
- the circuit actual oscillation frequency is directly proportional to the gas constant or absolute temperature of the gaseous medium whereby the circuit may be utilized as a gas ratio or temperature sensor.
- FIG. l is a block diagram of an electrofluidic delay line oscillator constructed in accordance with our invention.
- FIG. 2 is a view of a second embodiment of the delay line transducer portion of the oscillator illustrated in FIG. 1;
- FIG. 3 is a graphical representation of the oscillator frequency versus gas temperature characteristics of our electrofluidic delay line oscillator.
- the delay line is a tubing of predetermined length L corresponding of one or multiple half-wavelengths of a particular frequency of oscillation.
- the particular frequency may be described as a reference frequency corresponding to reference temperature and gas ratio conditions of a gaseous medium within the tubing.
- Tubing 10 is surrounded by the same gaseous medium that is within the tubing, and such gase' ous medium is, in general, a mixture of two known, dissimilar gases.
- the dissimilarity in the gas constants R of the two gases is preferably ofa high degree.
- Tubing 10 may be fabricated of any rigid material compatible with the gaseous medium employed such as plastic and metal.
- Tubing 10 may be a straight tube, as illustrated, or curved, the limitation being that no sharp bends be present.
- the tubing may be in a U-shaped form as shown in FIG. 2.
- the cross section of the tubing may be circular or noncircular.
- Tubing 10 is provided with an aperture illl located at each antinode of a reference frequency pneumatic pressure standing wave which is generated within the tubing in a manner to be described hereinafter.
- the aperture 11 is the passage means through the tubing wall for passage of the gaseous medium into and from the tubing.
- a single aperture 11 is located at the halfway point axially along the length of tubing 10.
- two apertures 111 are located at the one-third points along tubing 10 corresponding to the standing wave antinodes, and are illustrated in FIG. 1.
- the delay line length L corresponds to 3
- 5-n half-wavelengths at the reference frequency apertures of number 3, 4, 5-n are located at the antinodes of the standing waves, respectively.
- the apertures ll may be of virtually any shape, a rectangular shape with the narrow dimension along the longitudinal axis of the tubing being preferable since the area of such aperture may then be made sufficiently large for adequate passage of the gaseous medium through the tubing while assuring the edges of the aperture are located substantially at the antinode of the standing wave.
- the aperture dimension may be one-fourth by one-half of an inch.
- a first end of tubing 10 is suitably connected to the output of an electrical-to-pneumatic transducer 12 and the second end of the tubing is connected to the input of a pneumatic-toelectrical transducer 13.
- the output of transducer 13 is connected to the input of a conventional electronic amplifier l4 and the output of the amplifier is connected to the input of transducer 12 by means of conventional electrical conductors l5 and 16, respectively, to complete a closed loop circuit which includes the delay line, transducers and amplifier.
- Transducer l2 converts an electrical frequency signal to a pneumatic pressure frequency signal of the same frequency. This pneumatic signal generates a pneumatic pressure wave in the gaseous medium within tubing 10, thereby forming the aforementioned pneumatic pressure standing wave therein.
- the tubing wall guides the pressure wave to transducer 13.
- the maximum amplitude points of the standing wave occur at the ends of the tubing 10 and the zero value point(s) occur at the antinode(s) 111.
- a change in the operating frequency from the reference value results in a shift of the standing wave maximum and zero amplitude points.
- Transducer 13 converts the pneumatic pressure frequency signal within tubing 10 back to an electrical frequency signal of the same frequency which is then amplified by electronic amplifier 14 having sufficient gain to maintain self-sustained oscillation in the closed loop circuit.
- Amplifier 14 preferably also includes a bandpass filter wherein the midband frequency thereof is tuned to the oscillator reference frequency to thereby determine the frequency mode (harmonic) of circuit oscillation.
- the frequency of the pneumatic pressure oscillation in tubing 10 is:
- FIG. 3 illustrates typical operating characteristics of our pneumatic frequency signal is thence converted to an electrofluidic delay line oscillator.
- the gas medium being electrical frequency signal which is sufficiently amplified monitore i normal air.
- the graph is on a log-log scale and b lifi 14 t d i transducer 12 f tai i th depicts the increase in oscillator operating frequency with inpneumatic pressure frequency signal within tubing 10. Crease in air temperature in degrees Rankine.
- the delay line The band-pass filter, if utilized, has a midband frequency length p y in obtaining the 3 characteristics was 8 equal t th reference frequency -foot length of one-fourth-inch diameter copper tubing.
- An electrofluidic delay line oscillator comprising tubing means having a predetermined length corresponding to one or multiple half-wavelengths of a reference frequency of oscillation, said tubing means disposed in a gaseous medium and provided with an aperture located at an antinode of a reference frequency pneumatic pressure standing wave which may be generated within said tubing means, the aperture providing passage means through the tubing wall for the gaseous medium, said aperture being of rectangular shape with the narrow dimension along the longitudinal axis of the tubing means,
- an electrical-to-pneumatic transducer connected at a first end of said tubing means for converting an electrical frequency signal to a pneumatic frequency signal which generates a pneumatic pressure wave within said tubing 3 5 means
- a pneumatic-to-electrical transducer connected at a second end of said tubing means for converting the pneumatic frequency signal to an electrical frequency signal
- tubing 10 having an input connected to the output of said pneumatic-to-electrical transducer and an output connected to the input of said electrical-to-pneumatic transducer for providing sufficient gain to maintain the frequency signal as a self-sustaned oscillation in the closed loop circuit including said tubing means, said transducers and said electronic amplifier, the frequency of oscillation being tubing 10.
- tubing 10 must have appropriate location of apertures 11 when operating at a multiple halfwavelength standing wave.
- the gain of amplifier 14 may be made sufficiently low to maintain self-sustained oscillation in the closed loop circuit without saturation of the amplifier or transducers and thereby obtain a substantially sinusoidal varying frequency signal in both pneumatic form in tubing 10 and electrical form in the circuit external of the tubing.
- the gain of amplifier 14 may be increased to obtain saturation of at least one of the components 12, 13 and 14, most commonly the amplifier ing a repetition rate or frequency corresponding to the frequency hereinabove described.
- our delay line oscillatype frequency signals may be made sufficiently low to maintain self-sustained oscillation in the closed loop circuit without saturation of the amplifier or transducers and thereby obtain a substantially sinusoidal varying frequency signal in both pneumatic form in tubing 10 and electrical form in the circuit external of the tubing.
- the gain of amplifier 14 may be increased to obtain saturation of at least one of the components 12, 13 and 14, most commonly the amplifier ing a repetition rate or frequency corresponding to the frequency hereinabove described.
- Such piezoelectric-type transducers are probably the simplest type transducer that may be employed in our oscillator, although other conventional types may also be used.
- transducers l2 and 13 may also be of the electromagnetic type wherein transducer 12 is a conventional microphone and transducer 13 a conventional speaker.
- Transducer 12 may also be a capacitive-type microphone and transducer 13 an electrostatic-type speaker.
- the delay line oscillator set forth in claim 1 and further system including amplifier-filter 14 are located in a gaseous comprising m i b ng mohhol'edh reference frequency and a frequency meter connected in the closed loop circuit for corresponding length L of tubing 0 i SeleCted from the determining the actual frequency of oscillation therein above equation for a desired or reference value of gas d h b d i i h gas constant R h h bconstant R and gas temperature T.
- a conventional electronic olute t erature T i known, or the ab olute tem erafrequency meter 17 is connected in the circuit.
- the gas on ta t R i k the output of amplifier 14, for measuring the actual 3.
- the delay line oscillator set forth in claim 1 wherein frequency of oscillation in the circuit.
- tubing means is a curved length of tube fabricated from a rigid material.
Landscapes
- Physics & Mathematics (AREA)
- Acoustics & Sound (AREA)
- General Physics & Mathematics (AREA)
- Inductance-Capacitance Distribution Constants And Capacitance-Resistance Oscillators (AREA)
Abstract
A closed loop oscillator circuit consists of a tubing of predetermined length, an electrical-to-pneumatic transducer, a pneumatic-to-electrical transducer and an electronic amplifier. The electrical-to-pneumatic transducer converts an electrical frequency signal to a pneumatic frequency signal which generates pressure waves in a gaseous medium within the tubing. The tube length corresponds to one or multiple half-wavelengths of a reference frequency of oscillation. The electronic amplifier provides sufficient gain to maintain self-sustained oscillation in the closed loop circuit. The temperature or gas content (ratio) of the gaseous medium within the tubing can be determined from the actual oscillation frequency in the circuit.
Description
United States Patent ll9 67 Thompson et al.
[72] inventors Carl G. Ringwall 3,318,152 73/339 X Scotia; FOREIGN PATENTS gy schemdy will 171,988 3/1922 Great Britain 331/154 [21 1 APPL 3 Primary ExaminerRoy Lake [22] PH June 19, 9 9 Assistant Examtrzen-James B. MlliilllS paemed Nov. 16 1971 AltomeysDav1d M. Schrller, Arthur E. Foum1er,Jr., Frank [73] Assignee Gene, m Company w L. Neuhauser, Oscar B. Waddell and Joseph B. Forman [54] ELECTROFLUIDIC DELAY LINE OSCILLATOR l0Cli 3!) a in Fl s.
Fluid oscillator circuits are employed in many fluidic control systems for purposes such as generating pressurized fluid pulsations of fixed and variable frequency corresponding respectively to the reference and actual value of a system parameter being controlled. Oscillators which are all-fluidic (i.e., utilize fluid amplifiers having no moving mechanical parts) are known and have many useful applications; however, such conventional all-fluidic oscillators are generally not suitable in gas-monitoring systems wherein the fluid amplifiers are supplied with a pressurized gas other than the gaseous medium being sensed. Thus, in an application wherein an allfluidic oscillator is used to determine particular gas properties in a gas mixture, the introduction of a foreign gas via the fluid amplifier power fluid supply would result in a false indication of such properties.
Therefore, one of the principal objects of our invention is to provide a hybrid-type delay line oscillator.
Another object of our invention is to provide an electrofluidic delay oscillator adapted for determining particular properties of a gaseous medium.
A further object of our invention is to provide an electrofluidic delay line oscillator adapted for determining the gas content or temperature of a gas mixture of known gases.
Briefly summarized, our invention is an electrofluidic delay line oscillator which utilizes a tubing having a predetermined length corresponding to one or multiple half wavelengths of a particular or reference frequency of oscillation. The tubing is in a gaseous medium and is provided with an aperture located at each antinode of a reference frequency pneumatic pressure standing wave generated within the tubing, the aperture providing passage means through the tube wall for the gaseous medium. Suitable transducers and an electronic amplifier are connected in a closed loop circuit with the tubing, the amplifier providing sufficient gain to maintain self-sustained oscillation in the circuit. The circuit actual oscillation frequency is directly proportional to the gas constant or absolute temperature of the gaseous medium whereby the circuit may be utilized as a gas ratio or temperature sensor.
The features of our invention which we desire to protect herein are pointed out with particularity in the appended claims. The invention itself, however, both as to its organization and method of operation, together with further objects and advantages thereof, may best be understood by reference to the following description taken in connection with the accompanying drawings wherein:
FIG. l is a block diagram of an electrofluidic delay line oscillator constructed in accordance with our invention;
FIG. 2 is a view of a second embodiment of the delay line transducer portion of the oscillator illustrated in FIG. 1; and
FIG. 3 is a graphical representation of the oscillator frequency versus gas temperature characteristics of our electrofluidic delay line oscillator.
Referring now in particular to FIG. 1, there is shown our electrofluidic delay line oscillator in block diagram form. The delay line is a tubing of predetermined length L corresponding of one or multiple half-wavelengths of a particular frequency of oscillation. The particular frequency may be described as a reference frequency corresponding to reference temperature and gas ratio conditions of a gaseous medium within the tubing. Tubing 10 is surrounded by the same gaseous medium that is within the tubing, and such gase' ous medium is, in general, a mixture of two known, dissimilar gases. The dissimilarity in the gas constants R of the two gases is preferably ofa high degree. Tubing 10 may be fabricated of any rigid material compatible with the gaseous medium employed such as plastic and metal. Tubing 10 may be a straight tube, as illustrated, or curved, the limitation being that no sharp bends be present. As one example of a curved embodiment, the tubing may be in a U-shaped form as shown in FIG. 2. The cross section of the tubing may be circular or noncircular. Tubing 10 is provided with an aperture illl located at each antinode of a reference frequency pneumatic pressure standing wave which is generated within the tubing in a manner to be described hereinafter. The aperture 11 is the passage means through the tubing wall for passage of the gaseous medium into and from the tubing.
In the case of a single half wavelength standing wave (at reference frequency) generated within tubing 10, a single aperture 11 is located at the halfway point axially along the length of tubing 10. In the case of a two half-wavelength standing wave (again at reference frequency), two apertures 111 are located at the one-third points along tubing 10 corresponding to the standing wave antinodes, and are illustrated in FIG. 1. In like manner, for the case wherein the delay line length L corresponds to 3, 4, 5-n half-wavelengths at the reference frequency, apertures of number 3, 4, 5-n are located at the antinodes of the standing waves, respectively. The apertures ll may be of virtually any shape, a rectangular shape with the narrow dimension along the longitudinal axis of the tubing being preferable since the area of such aperture may then be made sufficiently large for adequate passage of the gaseous medium through the tubing while assuring the edges of the aperture are located substantially at the antinode of the standing wave. As a typical example, the aperture dimension may be one-fourth by one-half of an inch.
A first end of tubing 10 is suitably connected to the output of an electrical-to-pneumatic transducer 12 and the second end of the tubing is connected to the input of a pneumatic-toelectrical transducer 13. The output of transducer 13 is connected to the input of a conventional electronic amplifier l4 and the output of the amplifier is connected to the input of transducer 12 by means of conventional electrical conductors l5 and 16, respectively, to complete a closed loop circuit which includes the delay line, transducers and amplifier. Transducer l2 converts an electrical frequency signal to a pneumatic pressure frequency signal of the same frequency. This pneumatic signal generates a pneumatic pressure wave in the gaseous medium within tubing 10, thereby forming the aforementioned pneumatic pressure standing wave therein. The tubing wall guides the pressure wave to transducer 13. When the operating frequency of our delay line oscillator corresponds to the reference frequency, the maximum amplitude points of the standing wave occur at the ends of the tubing 10 and the zero value point(s) occur at the antinode(s) 111. A change in the operating frequency from the reference value results in a shift of the standing wave maximum and zero amplitude points. Transducer 13 converts the pneumatic pressure frequency signal within tubing 10 back to an electrical frequency signal of the same frequency which is then amplified by electronic amplifier 14 having sufficient gain to maintain self-sustained oscillation in the closed loop circuit. Amplifier 14 preferably also includes a bandpass filter wherein the midband frequency thereof is tuned to the oscillator reference frequency to thereby determine the frequency mode (harmonic) of circuit oscillation.
The frequency of the pneumatic pressure oscillation in tubing 10 is:
#nCyRTW /ZL Wherein R= equivalent gas constant of gaseous medium in tubing 10 11- equivalent specific heat ratio (C,,/C,,) of the gaseous medium T=absolute temperature of the gaseous medium n an integer corresponding to the mode of oscillation which can have the values 1, 2, 3,-n. The lowest mode (n =1) of frequency of oscillation operation of our delay line oscillator is obtained by having zero degrees phase shift in the electronic amplifier M whereby, assuming 14, and thereby obtain a substantially squarewave signal havtor can provide sinusoidal (analog) or squarewave (digital) there is no phase shift in the transducers, the delay line 10 the gas constant R thereof) the actual oscillator frequency operates at one-half a wavelength of the reference (i.e., the circuit operating frequency) changes in accordance frequency. Under these conditions, a pneumatic pressure with the square root relationship indicated in the equation wave is generated in tubing 10 (having one aperture 11) above.
at the fundamental of the reference frequency and this 5 FIG. 3 illustrates typical operating characteristics of our pneumatic frequency signal is thence converted to an electrofluidic delay line oscillator. The gas medium being electrical frequency signal which is sufficiently amplified monitore i normal air. The graph is on a log-log scale and b lifi 14 t d i transducer 12 f tai i th depicts the increase in oscillator operating frequency with inpneumatic pressure frequency signal within tubing 10. Crease in air temperature in degrees Rankine. The delay line The band-pass filter, if utilized, has a midband frequency length p y in obtaining the 3 characteristics was 8 equal t th reference frequency -foot length of one-fourth-inch diameter copper tubing.
A suitable change (integer multiple) of the midband it is apparent from the foregoing that our invention attains frequency in the band-pass filter and a corresponding selecthe objectives set forth in that it provides an electrofluidic tion of 180 (or multiples thereof) phase shift in amplifier obl 5 delay line Oscillator edapted for sehsihg a gas ratio (1 tains operation of our delay line oscillator in a desired mode Pressure of one 8 m a -8 mlxture, for Sensing the (n =2, 3,-n) which corresponds to harmonics of the n =1 temperature muhigas f more) mixture reference frequency and results in the corresponding multiple what f' clam as h and desh'e to Secure y letters Patem half-wavelengths of the pneumatic pressure standing wave in of the Umted Slates 1. An electrofluidic delay line oscillator comprising tubing means having a predetermined length corresponding to one or multiple half-wavelengths of a reference frequency of oscillation, said tubing means disposed in a gaseous medium and provided with an aperture located at an antinode of a reference frequency pneumatic pressure standing wave which may be generated within said tubing means, the aperture providing passage means through the tubing wall for the gaseous medium, said aperture being of rectangular shape with the narrow dimension along the longitudinal axis of the tubing means,
an electrical-to-pneumatic transducer connected at a first end of said tubing means for converting an electrical frequency signal to a pneumatic frequency signal which generates a pneumatic pressure wave within said tubing 3 5 means,
a pneumatic-to-electrical transducer connected at a second end of said tubing means for converting the pneumatic frequency signal to an electrical frequency signal, and
an electronic amplifier having an input connected to the output of said pneumatic-to-electrical transducer and an output connected to the input of said electrical-to-pneumatic transducer for providing sufficient gain to maintain the frequency signal as a self-sustaned oscillation in the closed loop circuit including said tubing means, said transducers and said electronic amplifier, the frequency of oscillation being tubing 10. Obviously, tubing 10 must have appropriate location of apertures 11 when operating at a multiple halfwavelength standing wave.
The gain of amplifier 14 may be made sufficiently low to maintain self-sustained oscillation in the closed loop circuit without saturation of the amplifier or transducers and thereby obtain a substantially sinusoidal varying frequency signal in both pneumatic form in tubing 10 and electrical form in the circuit external of the tubing. Alternatively, the gain of amplifier 14 may be increased to obtain saturation of at least one of the components 12, 13 and 14, most commonly the amplifier ing a repetition rate or frequency corresponding to the frequency hereinabove described. Thus, our delay line oscillatype frequency signals.
As a typical example of our delay line oscillator, the delay line 10 is fabricated of a one-half-inch inner diameter copper tube of l-foot length (reference frequency =550 Hz. for air and mode n =1 and the two transducers l2 and 13 are each of the piezoelectric type. Such piezoelectric-type transducers are probably the simplest type transducer that may be employed in our oscillator, although other conventional types may also be used. Thus, transducers l2 and 13 may also be of the electromagnetic type wherein transducer 12 is a conventional microphone and transducer 13 a conventional speaker. Transducer 12 may also be a capacitive-type microphone and transducer 13 an electrostatic-type speaker. Oscillation can be (YRT) 1/2 made to occur over a range of mode n=l to n=9 by apf=n propriately changing the midband frequency of the band-pass filter incorporated in the electronic amplifier component 14 where R is an equivalent gas constant of the gaseous medium,
and i utilizing ohe'foot copper tubing e g hzfving the P yis an equivalent specific heat ratio C of the gaseous mediproprlately located apertures at the antmo e points. No sigum, T is the absolute temperature of the gaseous medium, L is nificant change in oscillator performance is observed due to a the length of the tubing means and n is an integer which can greater number of apertures at the higher modes of frequency have the values 1, 2, Operaliehthe maximum amplitude points of the reference frequency Our delay line oscillation rs adapted for utility as a gas ratio standing wave occur at the ends of said tubing means and or g temperature sensor since the gas constant R each antinode aperture being located axially along said perature T ('ydoes not vary significantly) can be determined tubing means Spaced f the ends th f and from the above frequency relationship said electronic amplifier including a band-pass filter F"('Y wherein frequency is depehdet almost wherein the midband frequency thereof corresponds to entirely on the delay line length L and What is Often the reference frequency and determines the mode of described 85 the acoustic Velocity (V of the gas mixture oscillation in said tubing means corresponding to the Thus, in a typical application of our oscillator, the tubing 10 value f h n integer and t ansdu 1 and and Often the entire closed F 2. The delay line oscillator set forth in claim 1 and further system including amplifier-filter 14 are located in a gaseous comprising m i b ng mohhol'edh reference frequency and a frequency meter connected in the closed loop circuit for corresponding length L of tubing 0 i SeleCted from the determining the actual frequency of oscillation therein above equation for a desired or reference value of gas d h b d i i h gas constant R h h bconstant R and gas temperature T. A conventional electronic olute t erature T i known, or the ab olute tem erafrequency meter 17 is connected in the circuit. Preferably at re T h the gas on ta t R i k the output of amplifier 14, for measuring the actual 3. The delay line oscillator set forth in claim 1 wherein frequency of oscillation in the circuit. Thus, as the said pneumatic-to-electrical transducer and said electricaltemperature of a single-gas or multigas mixture changes, or to-pneumatic transducer are each of the piezoelectric the gas ratio of a two-gas mixture changes (thereby changing type.
4. The delay line oscillator set forth in claim 1 wherein said pneumatic-to-electrical transducer and said electricalto-pneumatic transducer are each of the electromagnetic type.
SVThe delay line oscillator set forth in claim 1 wherein said electronic amplifier provides a phase shift of or multiples of 180 to insure circuit operation in a desired mode of oscillation at one or multiple half-wavelengths of the actual frequency of oscillation in the circuit corresponding to the value of the n integer.
6. The delay line oscillator set forth in claim 1 wherein said electronic amplifier is provided with a sufficiently high gain to maintain the self-sustained oscillation in the closed loop circuit and saturation of said amplifier to thereby obtain a substantially square-wave signal in said tubing means and the circuit external thereof and having a repetition rate equal to the oscillator frequency.
7. The delay line oscillator set forth in claim 11 wherein said electronic amplifier is provided with a sufficiently low gain to maintain the self-sustained oscillation in the closed loop circuit without saturation of said amplifier or transducers to thereby obtain a substantially sinusoidal varying frequency signal in said tubing means and the circuit external thereof.
8. The delay line oscillator set forth in claim l wherein said tubing means is a straight length of tube fabricated from a rigid material.
9. The delay line oscillator set forth in claim 1 wherein said tubing means is a curved length of tube fabricated from a rigid material.
10. The delay line oscillator set forth in claim 9 wherein the curved length of tube is in a U-shaped form.
i l W l i
Claims (10)
1. An electrofluidic delay line oscillator comprising tubing means having a predetermined length corresponding to one or multiple half-wavelengths of a reference frequency of oscillation, said tubing means disposed in a gaseous medium and provided with an aperture located at an antinode of a reference frequency pneumatic pressure standing wave which may be generated within said tubing means, the aperture providing passage means through the tubing wall for the gaseous medium, said aperture being of rectangular shape with the narrow dimension along the longitudinal axis of the tubing means, an electrical-to-pneumatic transducer connected at a first end of said tubing means for convertinG an electrical frequency signal to a pneumatic frequency signal which generates a pneumatic pressure wave within said tubing means, a pneumatic-to-electrical transducer connected at a second end of said tubing means for converting the pneumatic frequency signal to an electrical frequency signal, and an electronic amplifier having an input connected to the output of said pneumatic-to-electrical transducer and an output connected to the input of said electrical-to-pneumatic transducer for providing sufficient gain to maintain the frequency signal as a self-sustained oscillation in the closed loop circuit including said tubing means, said transducers and said electronic amplifier, the frequency of oscillation being where R is an equivalent gas constant of the gaseous medium, gamma is an equivalent specific heat ratio CP/Cvof the gaseous medium, T is the absolute temperature of the gaseous medium, L is the length of the tubing means and n is an integer which can have the values 1, 2, 3,-n, the maximum amplitude points of the reference frequency standing wave occur at the ends of said tubing means and each antinode aperture being located axially along said tubing means spaced from the ends thereof, and said electronic amplifier including a bandpass filter wherein the midband frequency thereof corresponds to the reference frequency and determines the mode of oscillation in said tubing means corresponding to the value of the n integer.
2. The delay line oscillator set forth in claim 1 and further comprising a frequency meter connected in the closed loop circuit for determining the actual frequency of oscillation therein and thereby determining the gas constant R when the absolute temperature T is known, or the absolute temperature T when the gas constant R is known.
3. The delay line oscillator set forth in claim 1 wherein said pneumatic-to-electrical transducer and said electrical-to-pneumatic transducer are each of the piezoelectric type.
4. The delay line oscillator set forth in claim 1 wherein said pneumatic-to-electrical transducer and said electrical-to-pneumatic transducer are each of the electromagnetic type.
5. The delay line oscillator set forth in claim 1 wherein said electronic amplifier provides a phase shift of 0* or multiples of 180* to insure circuit operation in a desired mode of oscillation at one or multiple half-wavelengths of the actual frequency of oscillation in the circuit corresponding to the value of the n integer.
6. The delay line oscillator set forth in claim 1 wherein said electronic amplifier is provided with a sufficiently high gain to maintain the self-sustained oscillation in the closed loop circuit and saturation of said amplifier to thereby obtain a substantially square-wave signal in said tubing means and the circuit external thereof and having a repetition rate equal to the oscillator frequency.
7. The delay line oscillator set forth in claim 1 wherein said electronic amplifier is provided with a sufficiently low gain to maintain the self-sustained oscillation in the closed loop circuit without saturation of said amplifier or transducers to thereby obtain a substantially sinusoidal varying frequency signal in said tubing means and the circuit external thereof.
8. The delay line oscillator set forth in claim 1 wherein said tubing means is a straight length of tube fabricated from a rigid material.
9. The delay line oscillator set forth in claim 1 wherein said tubing means is a curved length of tube fabricated from a rigid material.
10. The delay line oscillator set forth in claim 9 wherein the curved length of tube is in a U-shaped form.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US83484069A | 1969-06-19 | 1969-06-19 |
Publications (1)
Publication Number | Publication Date |
---|---|
US3621453A true US3621453A (en) | 1971-11-16 |
Family
ID=25267944
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US834840A Expired - Lifetime US3621453A (en) | 1969-06-19 | 1969-06-19 | Electrofluidic delay line oscillator |
Country Status (1)
Country | Link |
---|---|
US (1) | US3621453A (en) |
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3726129A (en) * | 1969-11-25 | 1973-04-10 | Atomic Energy Authority Uk | System for measuring the resonant frequency of a body |
US4046008A (en) * | 1975-12-15 | 1977-09-06 | United Technologies Corporation | Fluidic temperature sensor |
US4595856A (en) * | 1985-08-16 | 1986-06-17 | United Technologies Corporation | Piezoelectric fluidic power supply |
US5581014A (en) * | 1995-04-05 | 1996-12-03 | Douglas; David W. | Method and apparatus for acoustic analysis of binary gas mixtures with continuous self-calibration |
US6786633B2 (en) * | 2001-02-07 | 2004-09-07 | Maquet Critical Care Ab | Method and arrangement for acoustically determining a fluid temperature |
GB2547284A (en) * | 2016-02-15 | 2017-08-16 | Ft Tech (Uk) Ltd | Sensor |
Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
GB171988A (en) * | 1920-11-24 | 1922-08-24 | Drahtlose Telegraphie Gmbh | Improved means for indicating the presence of noxious gases such as fire damp |
US1921501A (en) * | 1930-07-24 | 1933-08-08 | Ward E Bower | Oscillation generator |
US2949166A (en) * | 1957-06-27 | 1960-08-16 | United States Steel Corp | Apparatus for sonic treatment of gases and fluidized beds |
US3186226A (en) * | 1961-06-26 | 1965-06-01 | United States Steel Corp | Apparatus for determining the temperature of travelling strip |
US3214976A (en) * | 1960-10-28 | 1965-11-02 | Gen Dynamics Corp | Temperature measuring apparatus |
US3318152A (en) * | 1963-07-16 | 1967-05-09 | Westinghouse Electric Corp | Temperature sensor |
-
1969
- 1969-06-19 US US834840A patent/US3621453A/en not_active Expired - Lifetime
Patent Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
GB171988A (en) * | 1920-11-24 | 1922-08-24 | Drahtlose Telegraphie Gmbh | Improved means for indicating the presence of noxious gases such as fire damp |
US1921501A (en) * | 1930-07-24 | 1933-08-08 | Ward E Bower | Oscillation generator |
US2949166A (en) * | 1957-06-27 | 1960-08-16 | United States Steel Corp | Apparatus for sonic treatment of gases and fluidized beds |
US3214976A (en) * | 1960-10-28 | 1965-11-02 | Gen Dynamics Corp | Temperature measuring apparatus |
US3186226A (en) * | 1961-06-26 | 1965-06-01 | United States Steel Corp | Apparatus for determining the temperature of travelling strip |
US3318152A (en) * | 1963-07-16 | 1967-05-09 | Westinghouse Electric Corp | Temperature sensor |
Cited By (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3726129A (en) * | 1969-11-25 | 1973-04-10 | Atomic Energy Authority Uk | System for measuring the resonant frequency of a body |
US4046008A (en) * | 1975-12-15 | 1977-09-06 | United Technologies Corporation | Fluidic temperature sensor |
US4595856A (en) * | 1985-08-16 | 1986-06-17 | United Technologies Corporation | Piezoelectric fluidic power supply |
US5581014A (en) * | 1995-04-05 | 1996-12-03 | Douglas; David W. | Method and apparatus for acoustic analysis of binary gas mixtures with continuous self-calibration |
US6786633B2 (en) * | 2001-02-07 | 2004-09-07 | Maquet Critical Care Ab | Method and arrangement for acoustically determining a fluid temperature |
GB2547284A (en) * | 2016-02-15 | 2017-08-16 | Ft Tech (Uk) Ltd | Sensor |
WO2017141002A1 (en) * | 2016-02-15 | 2017-08-24 | Ft Technologies (Uk) Ltd | Acoustic resonance pressure and temperature sensor |
CN108713133A (en) * | 2016-02-15 | 2018-10-26 | 英国风拓技术有限公司 | Acoustic resonance pressure and temperature sensor |
GB2547284B (en) * | 2016-02-15 | 2019-11-06 | Ft Tech Uk Ltd | Acoustic resonator sensor for determining temperature |
US10837853B2 (en) | 2016-02-15 | 2020-11-17 | Ft Technologies (Uk) Ltd | Sensor |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
Van Wijngaarden | On the equations of motion for mixtures of liquid and gas bubbles | |
US3621453A (en) | Electrofluidic delay line oscillator | |
Ariaratnam | Random vibrations of non-linear suspensions | |
GB1093746A (en) | Improvements in fluid-signal resonators | |
US3458129A (en) | Fluidic frequency-to-analog circuit | |
CN103973225A (en) | High-impedance crystal resonator serial oscillating circuit and commissioning method thereof | |
US3465775A (en) | Temperature-insensitive fluid control circuits and flueric devices | |
GB1044117A (en) | Improvements in fluid mechanical oscillator | |
US3239027A (en) | Control apparatus | |
US3715912A (en) | Densitometer | |
Khmelev et al. | Measuring instrument of impedance characteristics of the ultrasonic vibrating systems | |
Warren | A comment on Gans' stability criterion for steady inviscid helical gas flows | |
Cunningham | Graphical solution of certain nonlinear differential-difference equations | |
US2731595A (en) | Phase shifting circuit | |
US3443080A (en) | Dividing circuit particularly adapted for measuring pressure relationships | |
US3139537A (en) | Low frequency square wave to sine wave shaper | |
US3287656A (en) | Variable frequency microwave discriminator | |
CN202421311U (en) | Digital detection device for amplitude of oscillating circuits | |
RU1810754C (en) | Slope angle-data transducer | |
Bottaccini et al. | Calibration of high-frequency manometers with the shock tube. | |
EP0076392A1 (en) | Bridge for reactive detector circuit | |
Nishida et al. | Low frequency oscillation in a high density plasma | |
SU945683A1 (en) | Ultrasonic device for measuring temperature | |
Miller | Experimental feasibility study of an analog electrical-to-fluidic transducer | |
Mattaboni et al. | Variable air transformer for impedance matching |